Signal processing device, audio-video display device and processing method

ABSTRACT

A signal processing device is disclosed, which includes a plurality of channel receivers, a plurality of time code processors in one-to-one correspondence with the channel receivers, a timing generator, a signal processor and a transmitter, wherein each channel receiver is configured to parse an audio-video signal which has a data format defined by the SDI protocol and including a time code that characterizes time information. Each time code processor is configured to extract the time code from a parsed audio-video signal obtained by a corresponding channel receiver, and form first frame image data including a frame time code. The signal processor is configured to form an absolute frame output image based on multiple channels of the first frame of image data, frame time codes therein, and an internal clock signal generated by the timing generator. The transmitter is configured to transmit the absolute frame output image for display.

RELATED APPLICATION

The present application claims the benefit of Chinese Patent ApplicationCN202010831032.1 filed on Aug. 18, 2020, the entire disclosure of whichis incorporated herein by reference.

FIELD

The present disclosure relates to the field of display technology,particularly to a signal processing device, an audio-video displaydevice and a processing method.

BACKGROUND

At present, signal processing devices applied to transmission ofaudio-video signals usually employ four 12G-SDI (serial digitalinterface) wires to transmit 8K ultra-high-definition audio-videosignals, or four 3G-SDI wires to transmit 4K ultra-high-definitionaudio-video signals, so that the signal transmission rate is very fast.However, during the actual use process, due to different qualities orlengths of the wires, delays of signals reaching an external displayterminal may be different. Therefore, an FPGA (Field Programmable GateArray) or SOC (System-on-a-Chip, system on chip) needs to be used toperform synchronization of input video signals.

Currently, an adjacent frame synchronization mechanism is mostly used insynchronization processing. The situation where there is excessivesignal delay between lines may result in misaligned and spliced display.

SUMMARY

The present disclosure provides a signal processing device, anaudio-video display device, and a processing method of the signalprocessing device so as to solve some or all of the above-mentionedproblems and other possible problems.

According to a first aspect of the present disclosure, there is provideda signal processing device applied to an audio-video signal, comprising:a plurality of channel receivers, a plurality of time code processors inone-to-one correspondence with the plurality of channel receivers, atiming generator, a signal processor, and a transmitter, wherein

each of the plurality of channel receivers is configured to parse anaudio-video signal received, wherein the audio-video signal has a dataformat defined by an SDI protocol and the data format comprises a timecode that characterizes time information;

each of the plurality of time code processors is configured to extractthe time code from a parsed audio-video signal obtained by acorresponding channel receiver through parsing and convert it into aframe time code that characterizes frame timing information, and form afirst frame image data comprising the frame time code and transmit it tothe signal processor;

the signal processor is configured to form an absolute frame outputimage based on multiple channels of the first frame image data, frametime codes in multiple channels of the first frame image data, and aninternal clock signal generated by the timing generator;

the transmitter is configured to transmit the absolute frame outputimage for display.

Optionally, the signal processor is further configured to communicatewith an external storage corresponding to the signal processing device,transmit multiple channels of the first frame image data to the externalstorage, respectively, and form an absolute frame output image accordingto multiple channels of second frame image data read from the externalstorage and the internal clock signal generated by the timing generator,wherein the multiple channels of second frame image data are image databelonging to a same absolute frame and formed by synchronizing themultiple channels of the first frame image data using the frame timecode in an absolute frame synchronization manner.

Optionally, the time code comprises hour data, minute data, second data,and frame data, wherein each of the plurality of time code processors isfurther configured to convert the frame data of the time code into aframe time code that characterizes frame timing information.

Optionally, the frame data comprises high-order frame data and low-orderframe data, wherein each of the plurality of time code processors isfurther configured to convert the low-order frame data of the frame datainto a frame time code that characterizes frame timing information.

Optionally, the signal processor comprises a bus arbiter, a pixelrearrangement processor, a plurality of input storages in one-to-onecorrespondence with the plurality of time code processors, and aplurality of output storages in one-to-one correspondence with theplurality of time code processors, wherein

each of the plurality of input storages is configured to transmit afirst frame image data from a corresponding time code processor to thebus arbiter;

the bus arbiter is configured to communicate with an external storagecorresponding to the signal processing device, transmit multiplechannels of the first frame image data to the external storage, and sendmultiple channels of second frame image data read from the externalstorage to corresponding output storages;

each of the plurality of output storages is configured to form thirdframe image data according to the internal clock signal and receivedsecond frame image data, and transmit the third frame image data to thepixel rearrangement processor;

the pixel rearrangement processor is configured to perform pixelrearrangement on multiple channels of the third frame image data andform an absolute frame output image.

Optionally, the transmitter comprises a V-By-One communication interfaceconfigured to transmit the absolute frame output image to an externaldisplay terminal.

According to a second aspect of the present disclosure, there isprovided an audio-video display device, comprising the signal processingdevice according to the first aspect of the present disclosure.

According to a third aspect of the present disclosure, there is provideda processing method using the signal processing device according to thefirst aspect of the present disclosure, comprising:

using each of the plurality of channel receivers to parse an audio-videosignal received, wherein the audio-video signal has a data formatdefined by an SDI protocol and the data format comprises a time codethat characterizes time information;

using the time code processor to extract the time code from a parsedaudio-video signal obtained by a corresponding channel receiver throughparsing and convert the time code into a frame time code thatcharacterizes frame timing information, and form first frame image datacomprising the frame time code and transmit it to the signal processor;

using the signal processor to form an absolute frame output image basedon multiple channels of the first frame image data, frame time codes inmultiple channels of the first frame image data, and an internal clocksignal generated by the timing generator;

using the transmitter to transmit the absolute frame output image fordisplay.

Optionally, said using the signal processor to form an absolute frameoutput image based on multiple channels of the first frame image data,frame time codes in multiple channels of the first frame image data, andan internal clock signal generated by the timing generator comprises:

using the signal processor to transmit multiple channels of the firstframe image data received to an external storage corresponding to thesignal processing device, respectively and form an absolute frame outputimage according to multiple channels of second frame image data readfrom the external storage and the internal clock signal, wherein themultiple channels of second frame image data are image data belonging toa same absolute frame and formed by synchronizing the multiple channelsof the first frame image data using the frame time code in an absoluteframe synchronization manner.

Optionally, the time code comprises hour data, minute data, second data,and frame data, and wherein said using the time code processor toconvert the time code into a frame time code that characterizes frametiming information further comprises:

using the time code processor to form a frame time code thatcharacterizes frame timing information according to the frame data ofthe time code.

Optionally, the frame data comprises high-order frame data and low-orderframe data, and wherein said using the time code processor to form aframe time code that characterizes frame timing information according tothe frame data of the time code further comprises:

using the time code processor to form a frame time code thatcharacterizes frame timing information according to the low-order framedata of the frame data.

Optionally, the signal processor comprises a bus arbiter, a pixelrearrangement processor, a plurality of input storages in one-to-onecorrespondence with the plurality of time code processors, and aplurality of output storages in one-to-one correspondence with theplurality of time code processors, wherein said using the signalprocessor to transmit multiple channels of the first frame image datareceived to an external storage corresponding to the signal processingdevice, respectively and form an absolute frame output image accordingto the multiple channels of second frame image data read from theexternal storage and the internal clock signal further comprises:

using each of the plurality of input storages to transmit the firstframe image data from a corresponding time code processor to the busarbiter;

using the bus arbiter to communicate with the external storagecorresponding to the signal processing device, transmit the multiplechannels of the first frame image data to the external storage, and sendthe multiple channels of second frame image data read from the externalstorage to corresponding output storages;

using the output storages to form third frame image data according tothe internal clock signal and the second frame image data, and transmitthe third frame image data to the pixel rearrangement processor;

using the pixel rearrangement processor to perform pixel rearrangementon multiple channels of the third frame image data and form an absoluteframe output image.

BRIEF DESCRIPTION OF THE DRAWINGS

In order to more clearly illustrate the technical solutions inembodiments of the present disclosure, the drawings to be used fordescription of the embodiments will be briefly introduced below.Obviously, the drawings described below are only some embodiments of thepresent disclosure. A person having an ordinary skill in the art mayalso obtain other drawings based on these drawings without spendinginventive efforts.

FIG. 1 illustrates a structural block diagram of a signal processingdevice according to an embodiment of the present disclosure;

FIG. 2 illustrates a structural block diagram of a signal processingdevice according to another embodiment of the present disclosure;

FIG. 3 illustrates a flow chart of a processing method performed using asignal processing device according to an embodiment of the presentdisclosure;

FIG. 4 illustrates a structural block diagram of an audio-video displaydevice according to an embodiment of the present disclosure.

DETAILED DESCRIPTION

In order to set forth the present disclosure more clearly, the presentdisclosure will be further described below in conjunction with optionalembodiments and the drawings. Similar components in the drawings aredenoted by the same reference numerals. Those skilled in the art shouldunderstand that contents specifically described below are illustrativerather than restrictive, and should not be used to limit the protectionscope of the present disclosure.

As shown in FIG. 1, an embodiment of the present disclosure provides asignal processing device 100 applied to an audio-video signal. Thesignal processing device 100 comprises a plurality of channel receivers110, a plurality of time code processors 120 in one-to-onecorrespondence with the plurality of channel receivers 110, a timinggenerator 130, a signal processor 140, and a transmitter 150. Each ofthe plurality of channel receivers 110 is configured to parse anaudio-video signal received, for example, from an external signalsource, wherein the audio-video signal has a data format defined by theSDI protocol and the data format includes a time code characterizingtime information. Each of the plurality of time code processors 120 isconfigured to extract the time code from the parsed audio-video signalobtained by a corresponding channel receiver through parsing and convertit into a frame time code characterizing frame timing information, andform first frame image data including the frame time code and transmitit to the signal processor. The signal processor 140 is configured toform an absolute frame output image based on multiple channels of thefirst frame image data, frame time codes in multiple channels of thefirst frame image data and an internal clock signal generated by thetiming generator 130. The transmitter 150 is configured to transmit theabsolute frame output image (for example, to an external displayterminal 160) for display. It is to be noted that the time informationcharacterized by the time code includes channel time information of acorresponding channel (also referred to as clock information thechannel).

In some embodiments, the signal processor is configured to communicatewith an external storage 170 corresponding to the signal processingdevice, transmit received multiple channels of the first frame imagedata to the external storage, respectively, and form an absolute frameoutput image according to multiple channels of second frame image dataread from the external storage and the internal clock signal generatedby the timing generator, wherein the multiple channels of second frameimage data are image data belonging to the same absolute frame andformed by synchronizing the multiple channels of the first frame imagedata using the frame time code in an absolute frame synchronizationmanner.

In this embodiment, the time code of the audio-video signal using theSDI protocol is utilized to synchronize the audio-video signalstransmitted by channels in the multiple channels (corresponding to thechannel receivers), thereby forming a synchronization mechanism thatperforms synchronization with an absolute frame. This can avoid thedisplay problem of misaligned frame splicing caused by excessive delaybetween frames during data transmission due to line problems, andeffectively enhance the synchronous transmission performance of theaudio-video signals, which can improve the user experience and has awide application prospect.

Specifically, when external audio-video signals are input into thesignal processing device through multiple channels, each channelreceiver of the signal processing device receives the audio-videosignals from the external signal source, and the audio-video signalincludes a time code of the timing information (i.e., the timeinformation described above) from the external signal source. Eachchannel receiver receives its audio-video signal in a serial manner, andtransmits the serially input audio-video signal to a corresponding timecode processor after converting it into a parallel signal and performingsignal processing.

The time code processor further parses the audio-video signal accordingto the data format defined by the SDI protocol, and parses out 58-bitbinary bit information. Time code formats of the SDI protocol are shownin Table 1. The time code formats in the SDI protocol are timeinformation including hour data, minute data, second data, and framedata.

TABLE 1 Time code formats of the SDI protocol Bits Definition  0-3low-order frame data  8-9 high-order frame data 16-19 low-order seconddata 24-26 high-order second data 32-35 low-order minute data 40-42high-order minute data 48-51 low-order hour data 56-57 high-order hourdata

In an optional embodiment, in consideration of the time range of thesignal delay resulting from the signal line transmission, the time codeprocessor may perform synchronization only using the frame data in thetime code format. That is, the frame data of the time code is convertedinto a frame time code that characterizes frame timing information. Forexample, the low-order frame data and the high-order frame data arespliced to form a frame time code using an 8-bit binary number, and thenthe same frame data identified by the frame time code is used to performabsolute frame synchronization, which can avoid the display problem ofmisaligned frame splicing caused by excessive delay between framesduring data transmission due to line problems, effectively enhance thesynchronous transmission performance of the audio-video signals, andimprove the user experience.

In another optional embodiment, considering that the capacity of thecorresponding external storage is limited, the time code processor ofthis embodiment may perform synchronization only using the low-orderframe data of the time code. That is, the low-order frame data of thetime code is converted into a frame time code that characterizes frametiming information. For example, the low-order frame data with a 4-bitbinary number is used to form a frame time code, and the same frame dataidentified by the frame time code is used to perform absolute framesynchronization.

The time code processor forms the received audio-video signal into firstframe image data including the frame time code, and transmits it to thesignal processor for absolute frame synchronization. Optionally, thesignal processor may communicate with an external storage correspondingto the signal processing device, transmit multiple channels of firstframe image data including frame time codes to the external storage, andform an absolute frame output image based on multiple channels of secondframe image data read from the external storage and the internal clocksignal generated by the timing generator and transmit it to thetransmitter. The absolute frame output image is sent to an externaldisplay terminal by the transmitter.

In other words, in the present disclosure, the time code of the SDIprotocol is used to form a frame signal (i.e., frame time code) forabsolute frame synchronization, the frame signal is used to performabsolute frame synchronization on input multiple channels of audio-videosignals, and then the clock signal of a local clock (i.e., timinggenerator) is used to control the output of the signal processingdevice, thereby realizing synchronization and signal processing of theinput multiple channels of audio-video signals to form an absolute frameoutput image that can be played by an external display terminal.

As shown in FIG. 2, in an optional embodiment, the signal processor 140comprises a bus arbiter 210, a pixel rearrangement processor 220, aplurality of input storages 230 and a plurality of output storages 240in one-to-one correspondence with the plurality of time code processors120, wherein each of the plurality of input storages 230 is configuredto transmit the first frame image data from a corresponding time codeprocessor to the bus arbiter. The bus arbiter 210 is configured tocommunicate with an external storage corresponding to the signalprocessing device, transmit multiple channels of the first frame imagedata to the external storage, and send multiple channels of second frameimage data read from the external storage to corresponding outputstorages. Each of the plurality of output storages 240 is configured toform third frame image data according to the internal clock signal andthe received second frame image data, and transmit the third frame imagedata to the pixel rearrangement processor. The pixel rearrangementprocessor 220 is configured to perform pixel rearrangement on multiplechannels of the third frame image data and form the absolute frameoutput image.

Specifically, the first frame image data output by each time codeprocessor is transmitted to a corresponding input storage at the risingedge of its vertical synchronization signal (VSYNC), and thecorresponding input storage transmits it to the bus arbiter. The busarbiter transmits the first frame image data of each channel to theexternal storage according to the bus arbitration sequence. In otherwords, the first frame image data is transmitted to the external storagebased on the clock signal of a corresponding channel.

The bus arbiter reads out multiple channels of second frame image datafrom the external storage. The multiple channels of second frame imagedata are image data belonging to the same absolute frame and formed bysynchronizing the multiple channels of first frame image data using theframe time code in an absolute frame synchronization manner. Themultiple channels of second frame image data are then transmitted tocorresponding output storages, respectively.

In order to unify the clocks for outputting image data, in each outputstorage, a third frame image with local clock information is formedusing the internal clock signal generated by the timing generator of thesignal processing device and the corresponding second frame image data,and transmitted to the pixel rearrangement processor.

The pixel rearrangement processor performs pixel rearrangement accordingto the received multiple channels of third frame image data to form aframe of image and outputs it to the transmitter, and the transmittertransmits the formed frame of image to an external display terminal forpresentation, thereby realizing synchronization and transmission ofmultiple channels of audio-video signals.

Specifically, the transmitter of this embodiment may comprise a VBO (VBy One, a digital interface standard dedicated to image transmission)communication interface, which is configured to transmit the absoluteframe output image to an external display terminal. That is, thetransmitter and the external display terminal establish a communicativeconnection through the VBO communication interface, and transmit datasignals.

In the foregoing embodiment, absolute frame synchronization is performedon the audio-video signals received by a plurality of channels receiversthrough the time code in the SDI protocol formats, which avoids thedisplay problem of misaligned frame splicing caused by excessive delaybetween frames during data transmission due to line problems,effectively enhances the synchronous transmission performance of theaudio-video signals, and improves the user experience.

It is to be noted that in the embodiments of the present disclosure, anyone of the time code processor, the signal processor, the bus arbiter,and the pixel rearrangement processor may be implemented as a processorand microprocessor including hardware (for example, one or moreprocessing cores), and a device or circuit with a data processingcapability such as a programmable logic device, for example, a time codeprocessing circuit, a signal processing circuit, a bus arbitrationcircuit, and a pixel rearrangement circuit. The timing generator may be,for example, any clock circuit capable of generating timing or a clock,such as a common quartz crystal oscillator. Any one of the externalstorage, the input storage, and the output storage described hereinincludes both a volatile memory and a non-volatile memory (for example,RAM, ROM, etc.).

An embodiment of the present application further provides a processingmethod using the signal processing device described above. Since theprocessing method provided by this embodiment of the present applicationcorresponds to the signal processing device provided by the severalembodiments described above, the technical means and effects in theforegoing embodiments are also applicable to the processing methodprovided by this embodiment, and will not be described in detail in thisembodiment.

As shown in FIG. 3, an embodiment of the present application furtherprovides a processing method using the signal processing devicedescribed above, comprising: using each of the plurality of channelreceivers to parse an audio-video signal received, for example, from anexternal signal source, wherein the audio-video signal has a data formatdefined by the SDI protocol and the data format includes a time codecharacterizing time information (S310); using the time code processor toextract a time code from a parsed audio-video signal obtained by acorresponding channel receiver through parsing and convert the time codeinto a frame time code characterizing frame timing information, and formfirst frame image data including the frame time code and transmit it tothe signal processor (S320); using the signal processor to form anabsolute frame output image based on multiple channels of first frameimage data, frame time codes in the multiple channels of first frameimage data, and an internal clock signal generated by the timinggenerator (S330); using the transmitter to transmit the absolute frameoutput image (for example, to an external display terminal) for display(S340). It is to be noted that the time information characterized by thetime code includes the clock information of a corresponding channel.

In some embodiments, at the time of using the signal processor to forman absolute frame output image based on multiple channels of first frameimage data, frame time codes in the multiple channels of first frameimage data, and an internal clock signal generated by the timinggenerator, the signal processor may be used to transmit the receivedmultiple channels of first frame image data to an external storagecorresponding to the signal processing device, respectively, and form anabsolute frame output image according to multiple channels of secondframe image data read from the external storage and the internal clocksignal, wherein the multiple channels of second frame image data areimage data belonging to the same absolute frame and formed bysynchronizing the multiple channels of first frame image data using theframe time code in an absolute frame synchronization manner.

In this embodiment, the time code of the audio-video signal using theSDI protocol is utilized to synchronize the audio-video signalstransmitted by channels in the multiple channels (corresponding to thechannel receivers), thereby forming a synchronization mechanism thatperforms synchronization with an absolute frame. This can avoid thedisplay problem of misaligned frame splicing caused by excessive delaybetween frames during data transmission due to line problems, andeffectively enhance the synchronous transmission performance of theaudio-video signals, which can improve the user experience and has awide application prospect. This embodiment is implemented in the sameway as the foregoing embodiments, which will not be repeated here.

In an optional embodiment, the time code includes hour data, minutedata, second data, and frame data. Using the time code processor toconvert the time code into a frame time code that characterizes frametiming information further comprises: using the time code processor toform a frame time code that characterizes frame timing informationaccording to the frame data of the time code.

In this embodiment, the low-order frame data and the high-order framedata in the time code can be spliced using a 8-bit binary number to forma frame time code, and then the same frame data identified by the frametime code is used to perform absolute frame synchronization, whichavoids the display problem of misaligned frame splicing caused byexcessive delay between frames during data transmission due to lineproblems, effectively enhances the synchronous transmission performanceof the audio-video signals, and improves the user experience.

Therefore, in an optional embodiment, the frame data includes high-orderframe data and low-order frame data. Using the time code processor toform a frame time code that characterizes frame timing informationaccording to the frame data of the time code further comprises: usingthe time code processor to form a frame time code that characterizesframe timing information according to the low-order frame data of theframe data.

In this embodiment, considering that the capacity of the correspondingexternal storage is limited, the low-order frame data with a 4-bitbinary number can be used to form a frame time code, and then the sameframe data identified by the frame time code can be used to performabsolute frame synchronization, which effectively enhances thesynchronous transmission performance of the audio-video signals andimproves the user experience.

In an optional embodiment, the signal processor comprises a bus arbiter,a pixel rearrangement processor, and a plurality of input storages andoutput storages in one-to-one correspondence with the plurality of timecode processors, respectively. Said using the signal processor totransmit the received multiple channels of first frame image data to anexternal storage corresponding to the signal processing device,respectively and form an absolute frame output image according tomultiple channels of second frame image data read from the externalstorage and the internal clock signal further comprises: using each ofthe plurality of input storages to transmit the first frame image datafrom a corresponding time code processor to the bus arbiter; using thebus arbiter to communicate with the external storage corresponding tothe signal processing device, transmit the multiple channels of firstframe image data to the external storage, and send multiple channels ofsecond frame image data read from the external storage to correspondingoutput storages; using the output storages to form third frame imagedata according to the internal clock signal and the second frame imagedata and transmitting the third frame image data to the pixelrearrangement processor; using the pixel arrangement processor toperform pixel rearrangement on multiple channels of third frame imagedata and form an absolute frame output image.

In this embodiment, absolute frame synchronization and signal processingare performed on multiple channels of audio-video signals by means ofthe input storage, the bus arbiter, the output storage, and the pixelrearrangement processor, thereby forming a frame of audio-video datathat can be played by an external display terminal. This effectivelyenhances the synchronous transmission performance of audio-videosignals, and improves the user experience.

Based on the signal processing device described above, an embodiment ofthe present disclosure provides an audio-video display device 400. Asshown in FIG. 4, the audio-video display device 400 comprises the signalprocessing device 100 described above.

In this embodiment, the audio-video display device may include anyproduct or component with a display function, such as a mobile phone, atablet computer, a television, a monitor, a notebook computer, a digitalphoto frame, or a navigator.

As described above, the present disclosure provides a signal processingdevice, an audio-video display device, and a processing method of thesignal processing device. By converting the time code in the audio-videosignal using the SDI protocol into a frame time code that characterizesframe timing information, and forming an absolute frame output image ofabsolute frame synchronization using the frame time code, the firstframe image data including the frame time code and the internal clocksignal, the situation of misaligned and spliced display is avoided,which effectively enhances the synchronous transmission performance ofaudio-video signals, improves the user experience, and has a wideapplication prospect.

Obviously, the foregoing embodiments of the present disclosure aremerely examples to clearly illustrate the present disclosure, and arenot intended to limit the implementation of the present disclosure. Fora person having an ordinary skill in the art, other variations orchanges in different forms may be further made on the basis of theforegoing description. Therefore, all obvious variations or changesderived from the technical solutions of the present disclosure are stillwithin the protection scope of the present disclosure.

1. A signal processing device applied to an audio-video signal,comprising: a plurality of channel receivers; a plurality of time codeprocessors in one-to-one correspondence with the plurality of channelreceivers; a timing generator; a signal processor; and a transmitter,wherein each of the plurality of channel receivers is configured toparse an audio-video signal received, wherein the audio-video signal hasa data format defined by an SDI protocol and the data format comprises atime code that characterizes time information, wherein each of theplurality of time code processors is configured to extract the time codefrom a parsed audio-video signal obtained by a corresponding channelreceiver through parsing and convert the time code into a frame timecode that characterizes frame timing information, and form a first frameimage data comprising the frame time code and transmit the first frameimage data to the signal processor, wherein the signal processor isconfigured to form an absolute frame output image based on multiplechannels of the first frame image data, frame time codes in multiplechannels of the first frame image data, and an internal clock signalgenerated by the timing generator, and wherein the transmitter isconfigured to transmit the absolute frame output image for display. 2.The signal processing device according to claim 1, wherein the signalprocessor is further configured to communicate with an external storagecorresponding to the signal processing device, transmit the multiplechannels of the first frame image data to the external storage,respectively, and form an absolute frame output image according tomultiple channels of second frame image data read from the externalstorage and the internal clock signal generated by the timing generator,and wherein the multiple channels of second frame image data are imagedata belonging to a same absolute frame and are formed by synchronizingthe multiple channels of the first frame image data using the frame timecode in an absolute frame synchronization manner.
 3. The signalprocessing device according to claim 1, wherein the time code compriseshour data, minute data, second data, and frame data, and wherein each ofthe plurality of time code processors is further configured to convertthe frame data of the time code into a frame time code thatcharacterizes frame timing information.
 4. The signal processing deviceaccording to claim 3, wherein the frame data comprises high-order framedata and low-order frame data, and wherein each of the plurality of timecode processors is further configured to convert the low-order framedata of the frame data into a frame time code that characterizes frametiming information.
 5. The signal processing device according to claim2, wherein the signal processor comprises a bus arbiter, a pixelrearrangement processor, a plurality of input storages in one-to-onecorrespondence with the plurality of time code processors, and aplurality of output storages in one-to-one correspondence with theplurality of time code processors, wherein each of the plurality ofinput storages is configured to transmit a first frame image data from acorresponding time code processor to the bus arbiter, wherein the busarbiter is configured to communicate with an external storagecorresponding to the signal processing device, transmit multiplechannels of the first frame image data to the external storage, and sendmultiple channels of second frame image data read from the externalstorage to corresponding output storages, wherein each of the pluralityof output storages is configured to form third frame image dataaccording to the internal clock signal and received second frame imagedata and transmit the third frame image data to the pixel rearrangementprocessor, and wherein the pixel rearrangement processor is configuredto perform pixel rearrangement on multiple channels of the third frameimage data and form an absolute frame output image.
 6. The signalprocessing device according to claim 1, wherein the transmittercomprises a V-By-One communication interface configured to transmit theabsolute frame output image to an external display terminal.
 7. Anaudio-video display device, comprising the signal processing deviceaccording to claim
 1. 8. The audio-video display device according toclaim 7, wherein the signal processor is configured to communicate withan external storage corresponding to the signal processing device,transmit the multiple channels of the first frame image data to theexternal storage, respectively, and form an absolute frame output imageaccording to multiple channels of second frame image data read from theexternal storage and an internal clock signal generated by the timinggenerator, and wherein the multiple channels of second frame image dataare image data belonging to a same absolute frame and formed bysynchronizing the multiple channels of the first frame image data usingthe frame time code in an absolute frame synchronization manner.
 9. Theaudio-video display device according to claim 7, wherein the time codecomprises hour data, minute data, second data, and frame data, andwherein each of the plurality of time code processors is furtherconfigured to convert the frame data of the time code into a frame timecode that characterizes frame timing information.
 10. The audio-videodisplay device according to claim 9, wherein the frame data compriseshigh-order frame data and low-order frame data, and wherein each of theplurality of time code processors is further configured to convert thelow-order frame data into a frame time code that characterizes frametiming information.
 11. The audio-video display device according toclaim 8, wherein the signal processor comprises a bus arbiter, a pixelrearrangement processor, a plurality of input storages in one-to-onecorrespondence with the plurality of time code processors, and aplurality of output storages in one-to-one correspondence with theplurality of time code processors, wherein each of the plurality ofinput storages is configured to transmit the first frame image data froma corresponding time code processor to the bus arbiter, wherein the busarbiter is configured to communicate with an external storagecorresponding to the signal processing device, transmit the multiplechannels of the first frame image data to the external storage, and sendthe multiple channels of second frame image data read from the externalstorage to corresponding output storages, wherein each of the pluralityof output storages is configured to form third frame image dataaccording to the internal clock signal and received second frame imagedata and transmit the third frame image data to the pixel rearrangementprocessor, and wherein the pixel rearrangement processor is configuredto perform pixel rearrangement on multiple channels of the third frameimage data and form an absolute frame output image.
 12. The audio-videodisplay device according to claim 7, wherein the transmitter comprises aV-By-One communication interface configured to transmit the absoluteframe output image to an external display terminal.
 13. A processingmethod using the signal processing device as claimed in claim 1,comprising: using each of the plurality of channel receivers to parse anaudio-video signal received, wherein the audio-video signal has a dataformat defined by an SDI protocol and wherein the data format comprisesa time code that characterizes time information; using at least one ofthe time code processors to extract the time code from a parsedaudio-video signal obtained by a corresponding channel receiver throughparsing and convert the time code into a frame time code thatcharacterizes frame timing information, and form first frame image datacomprising the frame time code and transmit it to the signal processor;using the signal processor to form an absolute frame output image basedon multiple channels of the first frame image data, frame time codes inmultiple channels of the first frame image data, and an internal clocksignal generated by the timing generator; and using the transmitter totransmit the absolute frame output image for display.
 14. The processingmethod according to claim 13, wherein said using the signal processor toform an absolute frame output image based on multiple channels of thefirst frame image data, frame time codes in multiple channels of thefirst frame image data, and an internal clock signal generated by thetiming generator comprises: using the signal processor to transmitmultiple channels of the first frame image data received to an externalstorage corresponding to the signal processing device, respectively andto form an absolute frame output image according to multiple channels ofsecond frame image data read from the external storage and the internalclock signal, wherein the multiple channels of second frame image dataare image data belonging to a same absolute frame and are formed bysynchronizing the multiple channels of the first frame image data usingthe frame time code in an absolute frame synchronization manner.
 15. Theprocessing method according to claim 13, wherein the time code compriseshour data, minute data, second data, and frame data, and wherein saidusing at least one of the time code processors to convert the time codeinto a frame time code that characterizes frame timing informationfurther comprises: using the at least one of the time code processors toform a frame time code that characterizes frame timing informationaccording to the frame data of the time code.
 16. The processing methodaccording to claim 15, wherein the frame data comprises high-order framedata and low-order frame data, and wherein said using the at least oneof the time code processors to form a frame time code that characterizesframe timing information according to the frame data of the time codefurther comprises: using the at least one of the time code processors toform a frame time code that characterizes frame timing informationaccording to the low-order frame data of the frame data.
 17. Theprocessing method according to claim 14, wherein the signal processorcomprises a bus arbiter, a pixel rearrangement processor, a plurality ofinput storages in one-to-one correspondence with the plurality of timecode processors, and a plurality of output storages in one-to-onecorrespondence with the plurality of time code processors, and whereinsaid using the signal processor to transmit multiple channels of thefirst frame image data received to an external storage corresponding tothe signal processing device, respectively and to form an absolute frameoutput image according to the multiple channels of second frame imagedata read from the external storage and the internal clock signalfurther comprises: using each of the plurality of input storages totransmit the first frame image data from a corresponding time codeprocessor to the bus arbiter; using the bus arbiter to communicate withthe external storage corresponding to the signal processing device,transmit the multiple channels of the first frame image data to theexternal storage, and send the multiple channels of second frame imagedata read from the external storage to corresponding output storages;using the output storages to form third frame image data according tothe internal clock signal and the multiple channels of second frameimage data, and to transmit the third frame image data to the pixelrearrangement processor; and using the pixel rearrangement processor toperform pixel rearrangement on multiple channels of the third frameimage data and to form an absolute frame output image.